slides

ASM: A Programmable Interface
for Extending Android Security
Research by:
Stephan Heuser, Adwair Nadkarni,
William Enck, Ahmad-Reza Sadeghi
From NC State and TU Darmstadt
Presented by: Jayce Gaines
What is ASM?
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ASM stands for the Android Security Modules framework.
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Most simply, the ASM is a framework that creates a series of
“authorization hooks” that allows developers to program and
define new reference modules for android.
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It allows a simple interface that these developers can use to
implement their applications without the need to change how
the operating system is set up.
The Android iOS
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Consumer operating systems are undergoing many changes.
•
Such changes are providing new abstractions for developers working
on user-applications.
•
Mobile operating systems are becoming more semantically rich and
are simplifying the development process.
The Android iOS
•
However, these changes are forcing the designers to rethink how
security is handled on their devices.
•
It is now a necessary for user applications to be placed under unique
protection domains, rather than simply executing with the user’s
authority.
•
Still, how and when privileges and access to the API’s should be
given has been very debated.
The Android iOS
•
Android has been a main focus of research for the last few years.
This is mainly attributed to it’s open source foundation and the
popularity of mobile devices.
•
There have been more than a dozen proposals from the research
community for new Android security architectures.
•
While these proposals have many different ideas and motivations,
they most often share the same types of authorization hooks and the
ASM seeks to assist with those goals.
What ASM is About
•
The primary goal of ASM is to promote security extensibility and
make the platform more accessible to potential security
enhancements.
•
ASM provides a set authorization hooks for building reference
monitors for Android security.
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ASM is designed to replace data values in OS APIs and allow thirdparty applications to define new ASM hooks.
Contributions
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Identify the authorization hook
semantics for new operating
systems, such as Android.
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Design and implement the ASM
framework.
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Implement two example ASM apps
for demonstration.
Background
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The Android OS is based on Linux but is substantially different
when dealing with application abstraction.
•
Android apps are commonly written in Java and then compiled into
special DEX bytecode that is used by the Dalvik virtual machine.
•
Android also defines four types of components: activity, service,
broadcast receiver and content provider.
The Components
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Activity components are responsible for handling the user interface.
•
Service components act as daemons which handle background
processing.
•
Broadcast receiver components handle asynchronous messages on
the system.
•
Content provider components are data servers that are queried by
other applications.
Binder & Parcels
•
These components communicate with each other using Binder
interprocess communication (IPC).
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Binder passes messages (called parcels) and also takes care of thread
management.
•
These parcels can pass references to other binder objects as well as
file descriptors.
•
When an app has a reference to a service component it can execute
remote procedure calls (RPCs) for methods defined by that service.
•
Most of Android’s APIs are implemented as RPCs to defined service
calls, which makes these very crucial.
Android Permissions
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Android enforces component security using permissions and defines
a core set of permissions that protect the OS resources and apps.
•
Third-party application developers can define new permissions that
are enforced using the same mechanisms as OS permissions.
•
Android then places authorization hooks that correspond and are
allowed to run OS service component methods.
Design Goals
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The authors sought to design a programmable interface for building new
security enhancements on the Android platform and set out to complete the
following goals:
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G1: Create generic authorization expressibility
G2: Ensure existing security guarantees
G3: Protect kernel integrity
G4: Multiple authorization modules
G5: Minimize resource overhead
Additionally ASM assumes that the base Android OS and services are
trusted and that third-party applications have complete control over their
address spaces.
 Any authorization hooks placed by the third-party app is untrusted.
 Third-party apps are trusted to mediate their own authorization hooks and
protection.
Design Goals (Cont.)
Generic Authorization Expressibility
 ASM provides the reference monitor interface hooks necessary to
develop both prior and future security enhancements for Android.
 Not all authorization will need all hooks provided and the different
hooks will be placed at different levels of authorization.
 This is so the enforcement semantics can be sufficiently
maintained.
Design Goals (Cont.)
Ensure Existing Security Guarantees
 Android allows third parties to extend it’s framework, essentially
allowing sandbox-like features.
 However, this can potentially break the built in security
framework’s guarantees. To fix this ASM’s reference monitors
interface hooks only allow fewer permissions and/or less file system
access.
 It should be noted that by allowing more restrictions some
expressibility will be lost.
Design Goals (Cont.)
Protect Kernel Integrity
 This is an extension of Goal 2, ensuring the existing security
remains viable and true.
 Some modules will require hooks within the kernel. These are
essential to providing the LSM interface to third-parties.
Design Goals (Cont.)
Multiple Authorization Modules
 Official support for multiple authorization modules on the platform
have not been adopted and could be of great benefit for the
developers.
 ASM could potentially support multiple authorization modules.
 However, allowing this requires carefully designing the
architecture to address possible conflicts.
Design Goals (Cont.)
Minimize Resource Overhead
 ASM should be designed so that when there is no authorization
module loaded, the system should have a negligible impact.
 Additionally, it is understood that not all authorization hooks will
be used by the modules.
 Since some hooks contribute more overhead than others, ASM is
designed so that only necessary hooks are enabled when needed
and the remaining are disabled.
Authorization Hook Semantics
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Many different academic and industry researchers have proposed security
enhancements to the Android OS.
•
These enhancements, while sometimes sharing similar concepts, do not
necessarily have the same motivation or design techniques.
 Some examples are as follows:
 Constraining permissions of installed apps
 Mediating communication between components
 Enforcing information control policies
 Tracking Android intent messages through applications
 Tracking privacy sensitive information
 Substitute fake information to protect user identification
 Etc.
Authorization Hook Semantics
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These works while having different implementation use a variety of
authorization hooks to communicate with the Android APIs.
Authorization Hook Semantics
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We can see from the table that nearly all of the proposals modify the Activity
Manager Service (AMS). This is to provide additional constraints on the
Inter-Component Communication (ICC).
•
The Package Manager Service (PMS) is also frequently modified, many
times for consistently updating permissions. Network Access and
Sensors/Phone Info are also often changed by many different security
implementations.
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It is important to note that ASM only considers mediation at the process
level. This means that applications such as TaintDroid and AppFence
cannot be built on top of ASM. This, however, does not mean that it will
remain the case in the future.
ASM Design
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ASM Provides a reference monitor interface for building new monitors. This
allows developers to focus on their new security enhancements, rather than
placing hooks.
ASM Design
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As shown, the ASM framework implements reference monitors as ASM
apps, with each app having to register for a unique set of authorization
hooks and callback.
•
When a protected operation is requested, ASM automatically invokes the
callback in the app and grants permission to the request.
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The ASM monitor interface is contained in the ASM bridge, which receives
protection events from authorization hooks. The hooks only trigger if it is
enabled.
 A protection event is an OS event requiring access control.
ASM Apps
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The reference monitors themselves are built as ASM apps and developed
with the same conventions and constraints as other Android apps.
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The core part of an ASM application is a service component that implements
the hook interface.
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Procedure for building an ASM application:
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ASM App Registration
Hook Registration
Handling Hook Callbacks
Registration Protection
ASM App Deployment
ASM Apps Procedure
ASM App Registration:
 An ASM app must register itself with the ASM Bridge after
installation. This can be done manually or can be done
automatically after the install is complete.
 When the ASM bridge receives a new registration, it updates its
persistent configuration.
 A reboot is required so that ASM apps receive all protection events
since boot. This is important because it could impact their
protection state.
ASM Apps Procedure
Hook Registration:
 The ASM app service component is started by ASM during the boot
process. At this point, it registers for the reference monitor
interface hooks in needs.
 Different hooks result in varying overhead costs, thus ASM app
developers are encouraged to only register for the hooks that are
necessary.
 If the ASM registers for third-party defined hooks the developer is
responsible for the naming conventions of the new hooks.
ASM Apps Procedure
Handling Hook Callbacks:
 Once registered, an app with receive a unique callback for each
corresponding protection event. The information of the callback will
be hook-specific.
 The ASM app returns the access control decision to the ASM
Bridge.
 ASM app developers must coordinate with the original application
developer for information passed to the callback.
ASM Apps Procedure
Registration Protection:
 Reference monitors are granted a high amount of privileges.
However, ASM doesn’t allow an ASM app to override the existing
Android security protections.
 ASM must protect the ability to receive callbacks and does this
using the existing Android permission model.
 By using the preconfigured permission model, it allows for easily
inspected ASM apps so that its abilities can be easily identified.
ASM Apps Procedure
ASN App Deployment
 How the ASM permissions are granted has a significant impact on the
practicality of security in the mobile device. It is known that end users
do not frequently read or understand Android’s install permissions.
 This can allow malware that exploits that lack of understanding and
gain ASM app privileges. This is partially mitigated by accomplishing
G2.
 It can be further prevented by using an alternative deployment model;
such as firmware signing keys, which prevent source code changes, or
by implementing an “unknown sources” setting that would prevent
non-Google certified apps from being installed.
ASM Bridge
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The ASM Bridge provides the reference monitor interface and coordinates the
protection events that occur in the authorization hooks.
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The bridge has three main components:
 Per-hook activation
 Callback Timeouts
 The Master Policy
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The Per-Hook Activation means that all the hooks for the ASM App start as
disabled. This keeps the overhead from exceeding an unreasonable amount while
the app is not loaded. The hooks are then enabled on a “by need” basis, to keep
the overhead down as much as possible.
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The Callback Timeouts allows the Bridge to set a time limit on the response time
for protection events. If a timeout occurs, the bridge assumes access to the
resource is denied.
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The Master Policy is in place to prevent collisions when multiple applications are
active at the same time. By default the policy is a consensus of all active ASM
apps. All apps must grant an access control decision for the action to be allowed.
Hook Types
ASM provides a reference monitor
interface for authorization hooks
placed throughout the Android OS. In
general they come in five different
categories:
 Lifecycle Hooks
 OS Service Hooks
 OS Content Provider Hooks
 Third-Party App Hooks
 LSM Hooks
Lifecycle Hooks
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Hooks in this category include: resolving intents, starting activities
and services, binding to services, dynamic registration of broadcast
receivers, and receiving broadcast intents.
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This type of hook is designed to refine the list of resolved
applications, based on access control policies.
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Lifecycle hooks are used most often at the beginning of component’s
establishment to determine intent and then to prevent the ASM from
adding new apps to the list which would override the OS’s
restrictions.
OS Service Hooks
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ASM apps require mediation for OS APIs providing functionality,
such as getting the geographic location of the device and taking
pictures. This is the main function of the OS Service Hooks.
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ASM uses Android’s AppOps subsystem to place the authorization
hooks. AppOps is an Android security enhancement that could
potentially be implemented as an ASM app itself.
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Using AppOps, OS Service hooks support graceful enforcement. This
means that, whenever possible, it will return empty data rather than
throwing an exception. This keeps the application running smoothly,
rather than risking volatile crashes.
Content Provider Hooks
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Content Provider Hooks are daemons that provide a relational
database interface for sharing information with other applications.
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Separate hooks are required and need to be authorized for the insert,
update, delete and query functions.
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It is possible improve performance of certain functions such as query;
however, this has resulted in increased number of function callbacks
which is a trade-off. The authors state that this is something they
intend to explore further in future work.
Third-Party Hooks
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ASM has the capabilities to allow third-party Android applications to
add hooks to the ASM Bridge. These hooks are useful for extending
enforcement in Google’s and the device manufacturer’s applications.
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Third-party hooks are identified by a unique hook name and the package
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The ASM Bridge sends messages to a special service to update the status of
a hook. The third-party developer must follow the message codes exactly for
proper hook management.
name of the application.
LSM Hooks
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ASM apps sometimes require mediation of UNIX-level objects such
as files or network sockets. By default, ASM cannot define
authorization hooks for those types of objects. Instead, special hooks
must be placed in the Linux Kernel.
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The main consideration for ASM is how to allow its apps to interact
with the LSM hooks, without overriding the security conventions
already in place.
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Currently, the ASM implementation uses a special ASM LSM that
implements the LSM hooks and makes upcalls to the ASM Bridge.
This retains the original conventions, while maintaining the
performance standards of ASM.
Evaluation & Conclusion
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ASM considerably simplifies
development of security modules.
Additionally, ASM minimizes
overhead that would normally be
incurred and retains acceptable
performance that does not interfere
with the user.
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We can also see similar results when
comparing overall energy
consumption when compared to the
normal amount of power usage. It is
almost unnoticeable.
Evaluation & Conclusion
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Overall, the Android Security Modules framework is similar to other
reference monitor interfaces that have been proposed in the past for Linux
and TrustedBSD.
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ASM is important because it is one of the first solutions of its kind for
Android mobile devices and can lead to unification and simpler
implementation of various security enhancements.
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ASM promotes the creation of additional and novel security improvements to
Android, while avoiding restricting OS consumers to a specific enforcement
policy.
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The authors believe that if ASM were to be integrated into the core source
code for Android, it could potentially allow researchers to add new reference
monitors to Android devices, without requiring root access.
The End.